Double-stranded ribonucleic acid for adjuvants

ABSTRACT

The invention provides a double-stranded ribonucleic acid (dsRNA) having a chain length suitable for simultaneously showing low toxicity and high function in the use of an adjuvant and the like, and resisting variation of chain length even when subjected to a heating and cooling treatment, or a salt thereof; an immune potentiator, adjuvant, pharmaceutical product and the like containing the dsRNA and the like; and a production method of such dsRNA and the like. The invention is characterized in that the weight average chain length of two or more single-stranded ribonucleic acids (ssRNAs) constituting the first chain constituting dsRNA is not more than ½ of the weight average chain length of one ssRNA constituting the second chain.

CROSS-REFERENCE TO RELATED APPLICATIONS

This patent application is a divisional of copending U.S. patentapplication Ser. No. 14/650,229, filed on Jun. 5, 2015, which is theU.S. national phase of International Patent Application No.PCT/JP2013/082774, filed Dec. 6, 2013, which claims the benefit ofJapanese Patent Application No. 2013-145471, filed on Jul. 11, 2013, andJapanese Patent Application No. 2012-267012, filed on Dec. 6, 2012,which are incorporated by reference in their entireties herein.

TECHNICAL FIELD

The present invention relates to a double-stranded ribonucleic acidhighly useful as a pharmaceutical product or pharmaceutical additive anda production method thereof.

BACKGROUND ART

Living organisms have natural immune system that quickly recognizes andeliminates pathogens such as virus, bacterium and the like that enteredthe living body. In the living organisms invaded by pathogens, airwayepithelial cells, dendritic cells and the like multilaterally recognizepartial structure of pathogens via natural immunoreceptors such asToll-like receptor, RIG-I-like receptor and the like, activate naturalimmunity and cause a natural immune response such as production of TypeI interferon (IFN) and inflammatory cytokines. The constituentcomponents of pathogens recognized by natural immunity and substancesmimicing same are called Immune Potentiators, and applied researchesthereof as an adjuvant for pharmaceutical products or vaccines areongoing. Particularly, in the use for infection vaccines and cancervaccines, its practicalization as an adjuvant capable of improving basicproperty while securing safety is expected. One of such immunepotentiators is artificially synthesized double-stranded ribonucleicacid (dsRNA).

Representative examples of the artificially synthesized dsRNA includepoly(A:U) wherein the single-stranded ribonucleic acids (ssRNAs)constituting a double-strand are adenylic acid homopolymer and uridylicacid homopolymer, poly(G:C) wherein ssRNAs constituting a double-strandare guanylic acid homopolymer and cytidylic acid homopolymer, polyICwherein ssRNAs constituting a double-strand are inosinic acidhomopolymer and cytidylic acid homopolymer, poly(I:C12U) wherein ssRNAsconstituting a double-strand are polymer C12U of an about 12:1 mixtureof cytidylic acid and uridylic acid and inosinic acid homopolymer, andthe like. These homo dsRNAs, particularly polyIC and poly(I:C12U), arecandidates for a therapeutic drug for viral diseases and anticancerdrugs, and a number of basic researches and application studies havebeen conducted. Among them are reports on the observation of sidereaction in non-clinical tests, and such finding is one of the mattersof concern that prevent practicalization.

When the efficacy and side reaction of dsRNA such as polyIC and the likeare discussed, the relationship with the chain length should be noted. Adiscussion with the knowledge of a finding that polyIC having a chainlength of several kbp or more shows stronger toxicity than short chainpolyIC is necessary.

The chain length as used in the present invention means the same as thebase number of RNA. The unit of the chain length of ssRNA is expressedin base or kilobase (1 kb=1000 bases), and that of dsRNA is expressed inbase pairs (bp) or kilobase pairs (1 kbp=1000 bp).

The weight average chain length of ssRNA and dsRNA is preferably a chainlength determined by a gel permeation chromatography (GPC) analysismethod. To be specific, GPC analysis is performed using dsRNA or dsDNAhaving a known molecular weight as a standard product, and average chainlength and median value of the chain length are calculated from theobtained data. Another method includes determining sedimentationcoefficient S (20,w) by a density gradient sedimentation velocitymethod, and estimating the chain length of ssRNA and dsRNA from anexperimental formula (The Journal of Biochemistry (1961)50:377).

Non-patent document 1 discusses the relationship between the chainlength of polyIC and median lethal dose (LD50) in mouse intraperitonealadministration and describes that LD50 of polyIC decreases as the chainlength becomes longer from 0.1 kbp to 6 kbp, namely, that the toxicitybecomes stronger. To be specific, LD50 of polyIC having a centrifugationsedimentation coefficient 11.6S (weight average chain length 2 kbp) isabout ⅕ to that of polyIC having a centrifugation sedimentationcoefficient 4.2S (weight average chain length 0.1 kbp), and about ⅔ tothat of polyIC having a centrifugation sedimentation coefficient 8.2S(weight average chain length 0.8 kbp). Patent document 1 describes thata mouse intravenously administered with polyIC having a centrifugationsedimentation coefficient of not less than 13S (i.e., weight averagechain length of not less than 3 kbp) showed a 61% decrease in the bonemarrow cell number, whereas a mouse intravenously administered withpolyIC having a centrifugation sedimentation coefficient of 8S (weightaverage chain length 0.75 kbp) did not show a decrease in the bonemarrow cell number. Similarly, a mouse intravenously administered withpoly(I:C12U) having a centrifugation sedimentation coefficient of notless than 13S showed a 59% decrease in the bone marrow cell number, anda mouse intravenously administered with poly(I:C12U) having acentrifugation sedimentation coefficient of 9S (weight average chainlength 1.0 kbp) did not show a decrease in the bone marrow cell number.

On the other hand, non-patent document 1 describes that the strength ofthe Type I IFN inducing action of polyIC and the induction time aremaintained more strongly and longer by polyIC having a longer chainlength. Non-patent document 2 describes that chemically synthesized 70bp polyIC shows RIG-I binding ability in mouse fetal fibroblasts but theIFNβ induction activity markedly decreases as compared to 1.2 kbppolyIC. Non-patent document 3 describes that the chain length of dsRNAnecessary for dsRNA dependent protein kinase reaction, which is one ofthe virus defense mechanisms that are activated by Type I IFN as asignal, and dsRNA dependent 2′,5′-oligoA synthetase reaction is not lessthan about 40-60 bp.

With such findings as background, the chain length of dsRNA thatfunctions as an adjuvant and has low toxicity is generally considered tobe preferably 0.1 kbp-2.0 kbp.

Artificial homo dsRNA is generally obtained by a production methodincluding synthesizing ssRNA by using ribonucleotide diphosphate as asubstrate and enzymes such as poly ribonucleotide nucleotidyltransferase and the like, and forming a double-strand by an annealingtreatment. The enzymatically synthesized ssRNA is, from the property ofthe enzymatic reaction, a mixture with various chain lengths. Inaddition, ssRNA is physicochemically unstable and, in our experience, aphosphodiester bond is broken in a neutral aqueous solution under anatmosphere of not less than about 50° C., thus resulting in the divisionof polymer. Furthermore, when homopolymers such as inosinic acid polymerand cytidylic acid polymer are annealed, plural ssRNAs are successivelylinked depending on the annealing conditions, as a result of which theaverage chain length of the resulting dsRNA becomes long. From suchtechnical background, dsRNA reagents commercially available at presentoften have different average chain lengths according to the makers andaccording to lots, and the toxicity thereof is also assumed to bedifferent for each product lot.

DOCUMENT LIST Patent Document

-   patent document 1: JP-A-1-238597

Non-Patent Documents

-   non-patent document 1: Japanese Journal of Microbiology (1976)    20(2): 71-76-   non-patent document 2: The Journal of Experimental Medicine (2008)    205(7): 1601-1610-   non-patent document 3: The Journal of Biological Chemistry (1980)    255(13): 6403-6407

SUMMARY OF THE INVENTION Problems to be Solved by the Invention

To utilize dsRNA showing varying effectiveness and toxicity depending onthe chain length for pharmaceutical products or clinical practice whilesecuring safety, dsRNA resisting change of chain length is desired.During various studies of the production method of dsRNA, the presentinventors encountered a phenomenon of formation of dsRNA having a chainlength longer than expected when RNAs having almost the same averagechain lengths were annealed. In one example, an inosinic acidhomopolymer having an average chain length of about 400 bases and acytidylic acid homopolymer having an average chain length of about 400bases were annealed by heating and cooling, polyIC having not less than2 kbp of redundant chain length components was produced. When polyIC wasannealed under mild temperature decrease conditions after variousstudies, the chain length components of not less than 2 kbp decreased tosome extent, but not less than 10 wt % remained even under the mostsuccessful conditions. When polyIC that showed decrease of not less than2 kbp of the chain length components was heated and cooled again in apractical time frame hardly influencing other pharmaceutical components,not less than 2 kbp of chain length components increased again.

By checking the document data in the past, the average chain length ofdsRNA produced by annealing ssRNAs having almost the same average chainlengths can be confirmed to be longer than the average chain lengths ofssRNAs constituting same. The above-mentioned non-patent document 1describes information showing the average chain length of polyICsubjected to the experiment and the average chain lengths of inosinicacid homopolymer and cytidylic acid homopolymer used as materialsthereof. In one example of data, polyIC produced by annealing aninosinic acid homopolymer with centrifugation sedimentation coefficient6.9S (weight average chain length 0.3 kb) and a cytidylic acidhomopolymer with 6.5S (weight average chain length 0.3 kb) is 16.0S(weight average chain length 5.6 kbp). Thus, the phenomenon of longchain formation due to annealing artificial homoRNA having almost thesame chain length occurs in any chain length area of from 2.2S (weightaverage chain length 0.05 kb) to 12.0S (weight average chain length 1.0kb) of the chain length of RNA used.

As a means for short chain formation of dsRNA that underwent long chainformation, some methods including physicochemical cutting such assonication, dry-heat treatment and the like are known. However, there isno study report on a production method suppressing long chain formationor a method of suppressing long chain formation from the structure ofdsRNA, not to mention a known technique relating to the structure ofdsRNA or means for preventing long chain formation thereof.

To use dsRNA for pharmaceutical products or use similar thereto,complete removal of pathogens such as mycoplasma, virus and the likehaving growth potential in the formulation process needs to be secured,for which heating sterilization is the most reliable treatment method.Therefore, a means for solving the serious problem in industrialutilization, that prevents practicalization of dsRNA-blended products,that it shows increased toxicity due to long chain formation by heatingand cooling, is also desired.

An object of the present invention is to provide a dsRNA or a saltthereof which is safe as a pharmaceutical product or an adjuvant forvaccine, and a production method thereof, and further a safe dsRNAblended product.

Means of Solving the Problems

The present inventors have conducted intensive studies in an attempt tosolve the aforementioned problems and found that long chain formation ofthe obtained dsRNA can be suppressed by setting the weight average chainlength of ssRNA constituting one of the chains of dsRNA to not more than½ to the weight average chain length of ssRNA constituting anotherchain. Furthermore, it was found that the thus-obtained dsRNA cansuppresses an increase in the long chain components when a heating andcooling treatment is applied. The present inventors have further studiedbased on the above-mentioned findings and completed the presentinvention.

Accordingly, the present invention relates to the following [1]-[7].

[1] A double-stranded ribonucleic acid (dsRNA) having a weight averagechain length within the range of 0.1 kilobase pairs (kbp) to 2.0 kbp, ora salt thereof, wherein

-   -   the first chain of said dsRNA consists of two or more        single-stranded ribonucleic acids (ssRNAs), and all of two or        more ssRNAs constituting said first chain are homopolymers        consisting of the same type of ribonucleotide,    -   the second chain of said dsRNA consists of one ssRNA, and each        of two or more ssRNAs constituting said first chain has a base        sequence having complementarity of a level capable of forming a        double strand to a partial region of one ssRNA constituting said        second chain, and    -   the weight average chain length of two or more ssRNAs        constituting said first chain is not more than ½ to the weight        average chain length of one ssRNA constituting said second        chain.        [2] The dsRNA or a salt thereof of the above-mentioned [1],        wherein said first chain is constituted of two or more ssRNAs        having a weight average chain length of 0.02-1.0 kilobase (kb).        [3] The dsRNA or a salt thereof of the above-mentioned [1] or        [2], wherein the weight ratio of dsRNA having a chain length of        not less than 2 kbp is not more than 10% when an operation of        heating said dsRNA or a salt thereof to 70° C. and cooling same        to 35° C. at a drop rate of 2° C./h, and thereafter an operation        of heating again to 70° C. and cooling same to 35° C. at an        average drop rate of 5° C./min are performed.        [4] The dsRNA or a salt thereof of any one of the        above-mentioned [1]-[3], wherein two or more ssRNAs constituting        said first chain is polyinosinic acid and one ssRNA constituting        said second chain is ssRNA comprising cytidylic acid at not less        than 80%.        [5] An immune potentiator, an adjuvant, or a pharmaceutical        product comprising the dsRNA or a salt thereof of any one of the        above-mentioned [1]-[4].        [6] A method of producing double-stranded ribonucleic acid        (dsRNA) having a weight average chain length within the range of        0.1 kilobase pairs (kbp) to 2.0 kbp, or a salt thereof,        comprising        (1) a step of preparing ssRNA consisting of the same type of        ribonucleotide,        (2) a step of preparing an ssRNA having a base sequence having        complementarity of a level capable of forming a double strand to        the aforementioned (1) ssRNA, and        (3) a step of annealing the aforementioned (1) ssRNA and the        aforementioned (2) ssRNA,        wherein the weight average chain length of ssRNA in the        aforementioned (1) is not more than ½ to that of the        aforementioned (2) and is 0.02-1.0 kilobase (kb).        [7] The method of the above-mentioned [6], wherein ssRNA of the        aforementioned (1) is a polyinosinic acid, and ssRNA of the        aforementioned (2) is ssRNA containing cytidylic acid at a ratio        of not less than 80%.

Effect of the Invention

Utilizing the findings disclosed in the present invention, a dsRNAresisting polymerization of dsRNAs, i.e., suppressing an increase in thetoxicity caused by long chain formation, and a highly safe immunepotentiator, adjuvant, vaccine and the like containing said dsRNA can beprovided. The present invention also provides a production method ofsuch dsRNA.

DESCRIPTION OF EMBODIMENTS

(dsRNA or a Salt Thereof)

The present invention provides a novel dsRNA or a salt thereof(hereinafter these are sometimes to be referred to generically as “dsRNAof the present invention”). The dsRNA of the present inventioncharacteristically has a weight average chain length within the range of0.1 kilobase pairs (kbp) to 2.0 kbp, wherein

the first chain of said dsRNA consists of two or more single-strandedribonucleic acids (ssRNAs), and all of two or more ssRNAs constitutingsaid first chain are homopolymers consisting of the same type ofribonucleotide,

the second chain of said dsRNA consists of one ssRNA, and each of two ormore ssRNAs constituting said first chain has a base sequence havingcomplementarity of a level capable of forming a double strand to apartial region of one ssRNA constituting said second chain, and

the weight average chain length of two or more ssRNAs constituting saidfirst chain is not more than ½ to the weight average chain length of onessRNA constituting said second chain.

As mentioned above, the first chain consists of two or more ssRNAs, andtherefore, in the dsRNA of the present invention, two or more ssRNAs asthe first chain may be bonded to ssRNA as the second chain via acomplementary bond between ribonucleotides. In this event, all ssRNAsconstituting the first chain constituting said dsRNA are not bonded viaa phosphodiester bond, but include plural ssRNAs not directly bonded. Inthe present specification, irrespective of whether or not all ssRNAs arelinked to form a “chain”, of the two chains constituting dsRNA, the sideconsisting of two or more ssRNAs is indicated as the first chain and theside consisting of one ssRNA is indicated as the second chain, forconvenience.

All ssRNAs constituting the first chain are homopolymers consisting ofthe same type of ribonucleotide. The ssRNA may be, unlimitatively, forexample, adenylic acid homopolymer, uridylic acid homopolymer, guanylicacid homopolymer, cytidylic acid homopolymer, inosinic acid homopolymerand the like.

ssRNA constituting the second chain has a base sequence complementary tossRNA of said first chain at a level capable of forming, in the useenvironment of the dsRNA of the present invention, a double strand witheach of two or more ssRNAs constituting the first chain. Accordingly,ssRNA as the second chain is not limited to a sequence wherein all basesare complementary to a base of ssRNA of the first chain. The use s15environment of dsRNA of the present invention presupposingadministration to the living body refers to, for example, the conditionof dissolving in saline at about 37° C. (pH about 7.4, sodium chlorideconcentration about 150 mM).

Therefore, for example, ssRNA as the second chain may be, obviously,ssRNA having a sequence combining one or plural kinds of ribonucleotidescomplementary to the ribonucleotide constituting each ssRNA of the firstchain, as well as ssRNA further incorporating, as long as thecomplementary bond with ssRNA of the first chain is not markedlyinhibited, ribonucleotide not complementary to the ribonucleotideconstituting each ssRNA of the first chain at a frequency of less than20%, preferably less than 10%, more preferably less than 5%, furthermore preferably less than 3%, particularly preferably less than 2%, mostpreferably less than 1%, in the all ribonucleotides constituting thessRNA. The complementarity between bases of ribonucleotide is well knownin the technical field.

To be specific, when the ssRNA of the first chain is an adenylic acidhomopolymer, ssRNA as the second chain may be, obviously, ssRNA of asequence combining one or plural kinds of ribonucleotides selected fromuridylic acid and inosinic acid, as well as ssRNA further incorporating,as long as the complementary bond with ssRNA of the first chain is notmarkedly inhibited, adenylic acid and/or guanylic acid and/or cytidylicacid and/or xanthylic acid at a frequency of less than 20%, preferablyless than 10%, more preferably less than 5%, further more preferablyless than 3%, particularly preferably less than 2%, most preferably lessthan 1%, in the all ribonucleotides constituting the ssRNA.

When the ssRNA of the first chain is a uridylic acid homopolymer, ssRNAas the second chain may be, obviously, ssRNA of a sequence of adenylicacid, as well as ssRNA further incorporating, as long as thecomplementary bond with ssRNA of the first chain is not markedlyinhibited, uridylic acid and/or guanylic acid and/or inosinic acidand/or cytidylic acid and/or xanthylic acid at a frequency of less than20%, preferably less than 10%, more preferably less than 5%, furthermore preferably less than 3%, particularly preferably less than 2%, mostpreferably less than 1%, in the all ribonucleotides constituting thessRNA.

When the ssRNA of the first chain is a guanylic acid homopolymer, ssRNAas the second chain may be, obviously, cytidylic acid homopolymer, aswell as ssRNA further incorporating, as long as the complementary bondwith ssRNA of the first chain is not markedly inhibited, uridylic acidand/or adenylic acid and/or guanylic acid and/or inosinic acid and/orxanthylic acid at a frequency of less than 20%, preferably less than10%, more preferably less than 5%, further more preferably less than 3%,particularly preferably less than 2%, most preferably less than 1%, inthe all ribonucleotides constituting the ssRNA.

When the ssRNA of the first chain is a cytidylic acid homopolymer, ssRNAas the second chain may be, obviously, ssRNA of a sequence combining oneor plural kinds of ribonucleotides selected from guanylic acid andinosinic acid, as well as ssRNA further incorporating, as long as thecomplementary bond with ssRNA of the first chain is not markedlyinhibited, adenylic acid and/or uridylic acid and/or cytidylic acidand/or xanthylic acid at a frequency of less than 20%, preferably lessthan 10%, more preferably less than 5%, further more preferably lessthan 3%, particularly preferably less than 2%, most preferably less than1%, in the all ribonucleotides constituting the ssRNA.

When the ssRNA of the first chain is an inosinic acid homopolymer, ssRNAas the second chain may be, obviously, ssRNA of a sequence combining oneor plural kinds of ribonucleotides selected from adenylic acid andcytidylic acid, as well as ssRNA further incorporating, as long as thecomplementary bond with ssRNA of the first chain is not markedlyinhibited, uridylic acid and/or guanylic acid and/or inosinic acidand/or xanthylic acid at a frequency of less than 20%, preferably lessthan 10%, more preferably less than 5%, further more preferably lessthan 3%, particularly preferably less than 2%, most preferably less than1%, in the all ribonucleotides constituting the ssRNA. In oneembodiment, ssRNA of the first chain is an inosinic acid homopolymer,ssRNA as the second chain is an ssRNA containing cytidylic acid at aratio of not less than 80%, ssRNA of the first chain is, for example, aninosinic acid homopolymer, and ssRNA as the second chain is a cytidylicacid homopolymer, and the like.

Whether the produced RNA has formed a double strand can be determinedby, for example, examining the temperature-absorbance curve utilizingthe difference between ssRNA and dsRNA in the absorption coefficient atAbs 260 nm. That is, the feature that the absorption at Abs 260 nmderived from nucleic acid base decreases by hydrogen bond of nucleicacid bases is utilized. To be specific, RNA sample is diluted withsaline, filled in a quartz cell, the absorbance is continuously measuredwhile gradually heating the quartz cell by a spectrophotometer equippedwith a temperature control function, and a temperature-absorbance curveis measured. When the sample is dsRNA, Abs 260 nm sharply increases fromthe temperature at which hydrogen bond between ssRNAs is broken anddissociation into ssRNA begins, and therefore, itstemperature-absorbance curve becomes a sigmoid curve. When the sample isan ssRNA mixture free of double strand formation, itstemperature-absorbance curve becomes linear.

The dsRNA of the present invention has a weight average chain lengthwithin the range of 0.1 kbp to 2.0 kbp, more preferably 0.1 kbp to 1.0kbp, further more preferably 0.2 kbp to 0.6 kbp.

In the dsRNA of the present invention, the weight average chain lengthof two or more ssRNAs constituting the first chain is not more than ½ tothat of one ssRNA constituting the second chain. Specifically, theweight average chain length of ssRNA constituting the first chain is,for example, 0.02-1.0 kb, preferably 0.02-0.4 kb, more preferably0.02-0.2 kb. On the other hand, the weight average chain length of ssRNAof the second chain is, for example, 0.04-2.0 kb, preferably 0.04-0.8kb, more preferably 0.04-0.4 kb. By setting the weight average chainlength of ssRNA constituting the first chain to, for example, 0.02-0.1kb, preferably 0.02-0.05 kb, and that of the second chain to, forexample, 0.2-1.0 kb, preferably 0.3-0.6 kb, dsRNA recognized by RLR butnot easily recognized by TLR-3 can be obtained.

As described above, the weight average chain length can be determined bya GPC analysis method. While the chain length may be calculated by anagarose gel electrophoresis method or polyacrylamide gelelectrophoresis, since electrophoresis buffer has a low saltconcentration, dsRNA may be problematically dissociated and cleavedpartially during electrophoresis and chain length distribution cannot beanalyzed with high precision. Therefore, chain length with low accuracywhich is estimated by an agarose gel electrophoresis method orpolyacrylamide gel electrophoresis cannot be compared with the datashown in the Examples of the present invention.

GPC analysis can be performed using a GPC analysis system mounting awater-soluble GPC analysis column. In this case, it is important toperform analysis while maintaining a high salt concentration of aneluent and low column temperature. Specifically, for example, GPCanalysis can be performed as follows. As a GPC analysis system, LCSolution GPC manufactured by Shimadzu Corporation is used,chromatography is performed in an isocratic mode, and absorbanceintensity at Abs 260 nm is measured. As the column, TSKgel G5000PWXL(manufactured by Tosoh Corporation) is used for the analysis of dsRNA of4000 bp or below. As a molecular weight marker, mononucleotide andoligonucleotide produced by an automatic synthesizer, and various DNAfragments of about 100 bp to about 4000 bp obtained by amplification ofsuitable DNA sequence by PCR method using λDNA as a template are used.

Analysis conditions are as described below.

-   -   eluent: 10 mM tris sulfuric acid buffer (pH 7.0), 150 mM sodium        sulfate    -   pump flow rate: 0.5 ml/min    -   column: TSK-Gel G-5000PWXL    -   column temperature: 25° C.    -   UV detection: Abs 260 nm

The absorbance intensity at Abs 260 nm output from LC-Solution GPC needsto be re-treated by spreadsheet software and the like. This is becausethe recorded absorbance data at Abs 260 nm show a product of RNAconcentration and chain length number of RNA, rather than theconcentration of RNA. Matrix of time-course absorbance data and GPCmolecular weight data recorded on LC-Solution GPC is loaded ontospreadsheet software, the base number is determined from the GPCmolecular weight, the absorbance is divided by the base number to givevalue A, value A and molecular weight data are statistically processedand weight average chain length and median value (chain length at whichvalue A becomes the local maximum) are determined. As the relationalformula of the base number of RNA synthesized by poly ribonucleotidenucleotidyl transferase and GPC molecular weight, the followingcalculation formula can be used.

for ssRNA

base number=(GPC molecular weight-98)/(NMP-18)

-   -   NMP: average molecular weight of nucleotide monophosphate

for dsRNA

base number=(GPC molecular weight-196)/(NMP1+NMP2−36)

-   -   NMP1: average molecular weight of sense side nucleotide        monophosphate    -   NMP2: average molecular weight of antisense side nucleotide        monophosphate

The structure of the 5′-terminal and 3′-terminal of dsRNA in the presentinvention may be any. Specifically, the 5′-terminal may be any ofhydroxyl, monophosphate, diphosphate and triphosphate, and the3′-terminal may be any of hydroxyl, monophosphate, diphosphate andtriphosphate.

Examples of the salt of dsRNA of the present invention include metalsalt, ammonium salt, organic amine addition salt, amino acid additionsalt and the like. Examples of the metal salt include alkali metal saltssuch as sodium salt, potassium salt and the like, alkaline earth metalsalts such as magnesium salt, calcium salt and the like, aluminum salt,zinc salt and the like. Examples of the ammonium salt include salts suchas ammonium, tetramethylammonium and the like. Examples of the organicamine addition salt include salts such as trishydroxyaminomethane andthe like. Examples of the amino acid addition salt include salts such aslysine, arginine, histidine, tryptophan, ornithine and the like.

(Immune Potentiator, Adjuvant, Pharmaceutical Product)

The dsRNA of the present invention may be added singly to vaccine andpharmaceutical products, or can be combined with other components orused in combination with drug forming techniques. For example,utilization as a hybrid polymer hydrogen bonded with a cationic polymersuch as polylysine, polyglutamic acid and the like, mixing with otherimmune potentiator having a different signal transduction pathway,utilization as a liposome preparation contained in or adsorbed tovarious liposome substrates such as oil-in-water type emulsion and thelike, utilization as a preparation for improving spreading capability bymixing with a thickener can be mentioned. Furthermore, it can also becombined with a drug delivery technique and a skin patch preparationtechnique. Furthermore, it can also be used by mixing with an immunepotentiator having a different signal transduction pathway.

The object of use of the dsRNA of the present invention, and a mixturethereof is not only improvement of the property of pharmaceuticalproducts having other active ingredients, such as vaccine, anticancerdrug, protein medicament, antibody medicament, nucleic acid medicamentand the like, but also utilization of dsRNA of the present invention asan active ingredient of pharmaceutical product, animal drug, fisherydrug. The dosage form may be any such as injection, nasal drop, eyedrop, percutaneous absorber and the like.

(Production Method)

The present invention also provides a production method of dsRNA or asalt thereof (hereinafter the production method of the presentinvention). The method includes

(1) a step of preparing ssRNA consisting of the same type ofribonucleotide,(2) a step of preparing an ssRNA having a base sequence havingcomplementarity of a level capable of forming a double strand to theaforementioned (1) ssRNA, and(3) a step of annealing the aforementioned (1) ssRNA and theaforementioned (2) ssRNA,wherein the weight average chain length of ssRNA in the aforementioned(1) is not more than ½ to that of the aforementioned (2) and is 0.02-1.0kilobase (kb).

ssRNA in steps (1), (2) can be similar to those described above as ssRNAconstituting the first chain and the second chain of dsRNA of thepresent invention, using which the dsRNA of the present invention can beproduced.

In steps (1), (2), ssRNA can be chemically synthesized using acommercially available RNA synthesizer and ribonucleotide monophosphateas a starting material. Also, it can be enzymatically synthesized fromribonucleotide triphosphate by using a commercially available RNApolymerase and deoxyribonucleic acid as a template. In addition, it canalso be synthesized enzymatically from ribonucleotide diphosphate byusing a commercially available poly ribonucleotide nucleotidyltransferase, without using a template. For preparation of ssRNA, forexample, a method described in a document [JP-A-2-227077] and the likemay also be utilized as appropriate.

While ssRNA enzymatically synthesized by poly ribonucleotide nucleotidyltransferase often has an average chain length exceeding 2 kb, ssRNA witha shorter chain length can be obtained by extending the reaction time.For short chain formation of RNA, any method can be used such assonication, dry-heat treatment of solid, alkali treatment, enzymatictreatment using an RNA degrading enzyme and the like.

Purification of synthesized ssRNA and purification of dsRNA obtained byannealing same can be performed by a known method such as dialysis,precipitate filtration, column purification and the like. Purified ssRNAand dsRNA can be acquired as an 1-20 mg/ml aqueous solution, or can beacquired as a solid by a further treatment such as freeze-drying and thelike.

The annealing operation in step (3) can be performed by a known methoddescribed in non-patent document 1 and the like. As ssRNA to be used forannealing, both purified ssRNA and unpurified ssRNA may be used.

When a salt of dsRNA is to be acquired, dsRNA obtained in the form of asalt may be directly purified, or dsRNA obtained in a free form may bedissolved in water, cation is added to form a salt, which may bepurified by a conventional method such as precipitate filtration, columnpurification and the like.

Experimental Examples and Comparative Examples are shown below.

Experimental Example 1. GPC Analysis

Inosinic acid homopolymer and cytidylic acid homopolymer enzymaticallysynthesized by poly ribonucleotide nucleotidyl transferase were dilutedwith sample diluent [10 mM tris sulfuric acid buffer (pH 7.0), 150 mMsodium sulfate], and subjected to GPC analysis. As the GPC analysissystem, LC Solution GPC manufactured by Shimadzu Corporation mountingTSKgel G5000PWXL packed column (manufactured by Tosoh Corporation) wasused, chromatography was performed in an isocratic mode, and absorbanceintensity at Abs 260 nm was measured. As a molecular weight marker,mononucleotide and oligonucleotide produced by an automatic synthesizer,and DNA fragments of about 4000 bp to about 100 bp obtained byamplification by PCR method using λDNA as a template were used.

The analysis conditions are as follows.

-   -   eluent: 10 mM tris sulfuric acid buffer (pH 7.0), 150 mM sodium        sulfate    -   pump flow rate: 0.5 ml/min    -   column: TSK-Gel G-5000PWXL    -   column temperature: 25° C.    -   detection: Abs 260 nm

Matrix of the time-course absorbance data and GPC molecular weight datarecorded on LC-Solution GPC was loaded onto spreadsheet software. Then,on the spreadsheet software, the base number (chain length) wascalculated from GPC molecular weight, the absorbance was divided by basenumber (chain length) to give value A, the corresponding data of thebase number (chain length) and value A were statistically processed, andthe weight average chain length and median value were calculated.Furthermore, wt % of the chain length component of not less than 2 kbwas calculated.

The calculation formulas used for calculation of the base numbers (chainlength) of the inosinic acid homopolymer and cytidylic acid homopolymerare as follows.

inosinic acid homopolymer: base number (chain length)=(GPC molecularweight-98)/330.2

cytidylic acid homopolymer: base number (chain length)=(GPC molecularweight-98)/305.2

The analysis results are shown in Table 1.

TABLE 1 weight average >2 kb sample chain length median value ratio namesubstance (base) (base) (wt %) pI-400 inosinic acid 389 381 0.9homopolymer pC-400 cytidylic acid 344 324 0.8 homopolymer

Comparative Example 1. Production of dsRNA

Inosinic acid homopolymer pI-400 was dissolved in annealing buffer[composition: 100 mM HEPES buffer (pH 6.5), 100 mM NaCl] to produce asolution (10 ml) such that Abs 260 nm of 50-fold diluent was 1.0.Similarly, cytidylic acid homopolymer pC-400 was dissolved in annealingbuffer to produce a solution (10 ml) such that Abs 260 nm of 50-folddiluent was 1.0. To a 50 ml plastic tube were added pI-400 solution (5ml) and pC-400 solution (5 ml), and two tubes containing the mixture wasproduced and stood at room temperature for 16 hr. 4M NaCl solution (0.5ml) and isopropyl alcohol (10 ml) were added and mixed in each tube,polyIC was precipitated by centrifugation at 2800×g for 10 min, and thecentrifugation supernatant was removed. 70% Ethanol (20 ml/tube) wasadded and mixed, polyIC was re-precipitated by centrifugation at 2800×gfor 10 min, and the centrifugation supernatant was removed. 70% Ethanol(20 ml/tube) was added again and mixed, polyIC was re-precipitated bycentrifugation at 2800×g for 10 min, and the centrifugation supernatantwas removed. The tube was placed in a desiccator, and remaining ethanolwas evaporated by drying under reduced pressure. Thereafter, annealingbuffer was added at 10 ml/tube to give polyIC (400:400) solutions #1 and#2 (#1 and #2 shows they were obtained by independent operation).

Comparative Example 2. GPC Analysis of dsRNA

The chain lengths of polyIC (400:400) #1 and #2 obtained in ComparativeExample 1 were analyzed by GPC analysis.

The GPC analysis was performed using the apparatus and proceduresdescribed in Experimental Example 1, and the correspondence data ofpolyIC base pairs number (chain length) and value A were statisticallyprocessed to calculate mean weight and median value. Furthermore, wt %of not less than 2000 base pairs (2 kbp) was calculated.

The polyIC chain length was calculated by the following calculationformula.

polyIC: chain length (bp)=(GPC molecular weight-196)/635.4

The calculation results are shown in Table 2.

It was clarified that polyIC produced by polymerizing inosinic acidhomopolymer having a weight average chain length of 389 bases which isshorter than 2 kb and cytidylic acid homopolymer having a weight averagechain length of 344 bases contains 42-43% (weight ratio) of chaincomponent of not less than 2 kbp which is considered to be problematic.The chain component of not less than 2 kbp is assumed to have beenformed by plural cytidylic acid homopolymer and inosinic acidhomopolymer used as materials, which are connected to each other.

TABLE 2 #1 #2 chain length (bp) >2 kbp chain length (bp) >2 kbp sampleweight median ratio weight median ratio name mean value (wt %) meanvalue (wt %) polyIC 993 792 42 1017 792 43 (400:400)

Comparative Example 3. Consideration of Heating and Cooling Conditions

The heating and cooling treatments were performed by the followingprocedures.

PolyIC (400:400) #1 and #2 produced in Comparative Example 1 were eachdispensed by 1 ml to a plastic tube (inner volume 1.5 ml) with a screwcap, and a heating and cooling treatment was performed under thefollowing conditions 1, 2 or 3.

Condition 1: After incubation in a warm bath (75° C.) for 3 min to raisethe product temperature to 70° C., the product was left standing at roomtemperature (about 26° C.). The time required for cooling to 35° C. wasabout 7 min, and an average temperature decrease rate was 5° C./min.

Condition 2: After incubation in a warm bath (75° C.) for 3 min to raisethe product temperature to 70° C., the heater power of the warm bath wasswitched off, and the product was allowed to gradually cool to 35° C.The time required for cooling to 35° C. was about 2 hr.

Condition 3: After incubation in a warm bath (75° C.) for 3 min to raisethe product temperature to 70° C., the heater power was switched off,and the warm water was allowed to naturally cool to 70° C. Using aprogrammed temperature controller, the product was gradually cooled from70° C. to 35° C. at a decrease rate of 2° C./h. The time required forcooling to 35° C. was 20 hr.

Comparative Example 4. GPC Analysis of dsRNA

The chain length of each sample obtained in Comparative Example 3 wasmeasured by GPC analysis explained in Comparative Example 2. The resultsare collectively shown in Table 3.

Since the average chain length of the polyIC (400:400) subjected to theheating and cooling treatment under condition 1, 2 or 3 is extremelysimilar between #1 and #2, the data can be said to be reproducibledistribution data of the chain length. While the ratio of the chaincomponent showing long chain formation to not less than 2 kbp decreasedmore in conditions with milder temperature decrease, it was 13% evenunder condition 3 which was the mildest of those performed at this time.In all samples, the median value of the chain length exceeded the meanweight, which clarifies that the main chain length componentconstituting the sample is a chain length component longer than the meanweight. It is assumed that a chain component containing plural inosinicacid homopolymers and cytidylic acid homopolymers connected to eachother constitutes the main part.

TABLE 3 #1 #2 heating chain length chain length and (bp) >2 kbp (bp) >2kbp cooling mean median ratio mean median ratio treatment weight value(wt %) weight value (wt %) condition 498 728 33 489 728 34 1 condition442 672 23 439 672 23 2 condition 401 622 13 406 622 13 3

Comparative Example 5. Analysis of Changes in Chain Length of PolyIC(400:400) by Re-Heating and Re-Cooling

Changes in the chain length by a re-heating treatment were examined. Inthe same manner as in Comparative Example 2, polyIC (400:400) #1 and #2were each dispensed by 1 ml to a plastic tube (inner volume 1.5 ml) witha screw cap, and a heating and cooling treatment was performed undercondition 3, which was followed by the second heating and coolingtreatment under condition 1 or condition 2. GPC analysis and chainlength analysis of the samples after the heating and cooling treatmentswere performed. The results are collectively shown in Table 4. The ratioof not less than 2 kbp that decreased to 13% by the heating and coolingtreatment under condition 3 increased again to 32-33% or 18-21% by there-treatment under condition 1 or condition 2. That is, it was clarifiedthat even polyIC (400:400) after a treatment for suppressing productionof the chain component to not less than 2 kbp shows a sharp increase inthe ratio of the chain component to not less than 2 kbp when it isre-heated.

TABLE 4 #1 #2 chain length chain length heating and (bp) >2 kbp (bp) >2kbp cooling weight median ratio weight median ratio treatment mean value(wt %) mean value (wt %) first time: 401 622 13 406 622 13 condition 3second time: not performed first time: 466 672 33 470 672 32 condition 3second time: condition 1 first time: 451 622 21 407 622 18 condition 3second time: condition 2

Examples of the present invention are shown below, to which the presentinvention is not limited.

Example 1

Production of polyIC (25:400)

Inosinic acid homopolymer pI-25 (weight average chain length 29 bases,median value 29 bases) was dissolved in annealing buffer [composition:100 mM HEPES buffer (pH 6.5), 100 mM NaCl] to produce a solution (10 ml)such that Abs 260 nm of 50-fold diluent was 1.0. Similarly, pC-400(weight average chain length 344 bases, median value 324 bases) wasdissolved in annealing buffer to produce a solution (10 ml) such thatAbs 260 nm of 50-fold diluent was 1.0. To a 50 ml plastic tube wereadded pI-400 solution (5 ml) and pC-25 solution (5 ml), and two tubescontaining the mixture was produced and stood at room temperature for 16hr. 4M NaCl solution (0.5 ml) and isopropyl alcohol (10 ml) were addedand mixed in each tube, polyIC was precipitated by centrifugation at2800×g for 10 min, and the centrifugation supernatant was removed. 70%Ethanol (20 ml/tube) was added and mixed, polyIC was re-precipitated bycentrifugation at 2800×g for 10 min, and the centrifugation supernatantwas removed. 70% Ethanol (20 ml/tube) was added again and mixed, polyICwas re-precipitated by centrifugation at 2800×g for 10 min, and thecentrifugation supernatant was removed. The tube was placed in adesiccator, and remaining ethanol was evaporated by drying under reducedpressure. Thereafter, annealing buffer was added at 10 ml/tube toproduce polyIC (25:400) solutions #1 and #2 (#1 and #2 shows they wereobtained by independent operation).

In the same manner as in Comparative Example 2, GPC analysis of polyIC(25:400) solution was performed and chain length analysis was performed.

Furthermore, using polyIC (25:400) solutions #1 and #2, samples thatunderwent a heating and cooling treatment under condition 1 andcondition 2 were prepared by the same procedures as in ComparativeExample 3, and GPC analysis and chain length analysis were performed.The analysis results are collectively shown in Table 5.

polyIC (25:400) did not show a long chain formation phenomenon of thechain length as observed with polyIC (400:400), and even when a heatingand cooling treatment was applied, a phenomenon in which a chaincomponent containing plural inosinic acid polymers and cytidylic acidpolymers connected to each other becomes the main part was not observed.

TABLE 5 #1 #2 heating chain length chain length and (bp) >2 kbp (bp) >2kbp cooling mean median ratio mean median ratio treatment weight value(wt %) weight value (wt %) untreated 256 203 1 258 203 1 condition 256203 1 261 220 1 1 condition 254 203 1 254 203 1 2

Example 2

Production of polyIC (50:400)

In the same manner as described in Example 1 except that pI-25 waschanged to inosinic acid homopolymer pI-50 (weight average chain length41 bases, median value 35 bases), polyIC (50:400) solutions #1 and #2were produced (#1 and #2 show they were obtained by independentoperations). GPC analysis and chain length analysis of the polyIC(50:400) solutions were performed in the same manner as in ComparativeExample 2. Furthermore, using polyIC (50:400) solutions #1 and #2,samples that underwent a heating and cooling treatment under condition 1and condition 2 were prepared by the same procedures as in ComparativeExample 3, and GPC analysis and chain length analysis were performed.The analysis results are collectively shown in Table 6.

polyIC (50:400) did not show a long chain formation phenomenon of thechain length as observed with polyIC (400:400), and even when a heatingand cooling treatment was applied, a phenomenon in which a chaincomponent containing plural inosinic acid polymers and cytidylic acidpolymers connected to each other becomes the main part was not observed.

TABLE 6 #1 #2 heating chain length chain length and (bp) >2 kbp (bp) >2kbp cooling mean median ratio mean median ratio treatment weight value(wt %) weight value (wt %) untreated 288 239 1 288 239 1 condition 278220 1 275 220 1 1 condition 268 203 1 268 203 1 2

Example 3

Production of polyIC (100:400)

In the same manner as described in Example 1 except that pI-25 waschanged to inosinic acid homopolymer pI-100 (weight average chain length108 bases, median value 95 bases), polyIC (100:400) solutions #1 and #2were produced (#1 and #2 show they were obtained by independentoperations). Furthermore, using a part of polyIC (100:400) #1, a samplethat underwent the heating and cooling treatment under condition 1 inComparative Example 3 and a sample that underwent the heating andcooling treatment under condition 2 were prepared. Similarly, usingpolyIC (100:400) #2, samples that respectively underwent a heating andcooling treatment under condition 1 and condition 2 were prepared by thesame procedures as in Comparative Example 3, and GPC analysis and chainlength analysis of the respective samples were performed in the samemanner as in Comparative Example 2. The analysis results arecollectively shown in Table 7.

polyIC (100:400) did not show a long chain formation phenomenon of thechain length as observed with polyIC (400:400). The average chain lengthwas somewhat different between #1 and #2 tubes, but the tubes after aheating and cooling treatment scarcely showed a difference. The ratio ofthe long chain component of not less than 2 kbp of the samples after theheating and cooling treatment was equivalent to that of the sampleswithout the heating and cooling treatment, and even when a heating andcooling treatment was applied, a phenomenon in which a chain componentcontaining plural inosinic chain polymers and cytidylic acid polymersconnected to each other becomes the main part was not observed.

TABLE 7 #1 #2 heating chain length chain length and (bp) >2 kbp (bp) >2kbp cooling mean median ratio mean median ratio treatment weight value(wt %) weight value (wt %) untreated 302 349 3 339 404 4 condition 303187 4 315 203 4 1 condition 249 173 2 272 187 2 2

PolyIC (100:400) #1 and polyIC (100:400) #2 that underwent the heatingand cooling treatment under condition 2 in the above were subjectedagain to the heating and cooling treatment under the above-mentionedcondition 1, and the GPC analysis and chain length analysis wereperformed. The results are shown in Table 8.

PolyIC (100:400) did not show a long chain formation phenomenon of thechain length as observed with polyIC (400:400), and even when are-heating and re-cooling treatment was applied, an increase in the longchain component was not observed.

TABLE 8 #1 #2 heating chain length chain length and (bp) >2 kbp (bp) >2kbp cooling mean median ratio mean median ratio treatment weight value(wt %) weight value (wt %) first time: 249 173 2 272 187 2 condition 2second time: not performed first time: 272 258 4 276 279 4 condition 2second time: condition 1

Example 4

Production of polyIC (200:400)

In the same manner as described in Example 1 except that pI-25 waschanged to inosinic acid homopolymer pI-200 (weight average chain length188 bases, median value 157 bases), polyIC (200:400) solutions #1 and #2were produced (#1 and #2 show they were obtained by independentoperations). GPC analysis and chain length analysis of the polyIC(200:400) solutions were performed in the same manner as in ComparativeExample 2. Furthermore, using polyIC (200:400) #1 and #2, samples thatunderwent a heating and cooling treatment under condition 1, condition 2or condition 3 were prepared by the same procedures as in ComparativeExample 3, and GPC analysis and chain length analysis were performed.The results are collectively shown in Table 9.

PolyIC (200:400) showed an increase in the long chain component of notless than 2 kbp up to 12-16%, but the long chain formation phenomenondecreased due to a heating and cooling treatment, and was almostcompletely suppressed by the heating and cooling treatment undercondition 3 that provides most moderate cooling.

TABLE 9 #1 #2 heating chain length chain length and (bp) >2 kbp (bp) >2kbp cooling mean median ratio mean median ratio treatment weight value(wt %) weight value (wt %) untreated 377 537 12 413 537 16 condition 379500 10 389 500 11 1 condition 313 301  5 327 325  6 2 condition 244 134 1 298 146  3 3

Using the above-mentioned polyIC (200:400) #1 and #2 and in the samemanner as in Comparative Example 3, samples that underwent the heatingand cooling treatment under condition 3, followed by the second heatingand cooling treatment under condition 1 or 2, were respectivelyprepared. GPC analysis and chain length analysis of the prepared sampleswere performed. The results are collectively shown in Table 10.

When polyIC (200:400) treated under condition 3 was re-heated andre-cooled under condition 1, the ratio of not less than 2 kbp increasedto 9% and the chain component of not less than 2 kbp tended to increasesomewhat. However, the ratio thereof was lower than the ratio of notless than 2 kbp (10-11%) (Table 9) obtained when polyIC (200:400) wassubjected to the cooling and heat treatment under the same conditions.In the sample treated under condition 3 and re-treated under condition2, the ratio of not less than 2 kbp was 4% and scarcely increased. Thatis, in polyIC (200:400), a severe increase in the long chain componentof not less than 2 kbp due to the re-heating and re-cooling treatmentobserved in polyIC (400:400) was not observed.

TABLE 10 #1 #2 heating chain length chain length and (bp) >2 kbp (bp) >2kbp cooling mean median ratio mean median ratio treatment weight value(wt %) weight value (wt %) first time: 244 134 1 298 146 3 condition 3second time: not performed first time: 356 434 9 363 466 9 condition 3second time: condition 1 first time: 309 123 4 317 123 4 condition 3second time: condition 2

Experimental Example 2: Comparative Test of Recognition Property ofVarious PolyICs by TLR-3 and RLR Background

Animal cells are provided with three natural immune receptors thatrecognize dsRNA, which are Toll like receptor-3 (TLR-3) belonging to theTLR family, and Retinoic acid-inducible gene-I (RIG-I) and Melanomadifferentiation-Associated protein 5 (MDA-5) belonging to the RLRfamily. TLR-3 is a receptor localized in the endosome of the cell. WhendsRNA is bonded thereto, signal transduction via TRIF occurs and Type Iinterferon (IFN) and inflammatory cytokines are induced. The cellsexpressing TLR-3 are limited to particular immunocompetent cells such asmyeloid dendritic cell, fibroblast and the like. On the other hand,RIG-I and MDA-5, which are generically referred to as RIG-I likereceptor (RLR), are both localized in the cytoplasm of the cell, andhave a dsRNA binding domain called CARD domain. When dsRNA is bonded tothe CARD domain, signal transduction occurs via IPS1 in both RIG-I,MDA-5, and Type I IFN and inflammatory cytokines are induced. RLR is areceptor expressed in any cell including immunocompetent cells. RIG-Iand MDA-5 show different recognition properties depending on the chainlength of dsRNA and 5′-terminus structure.

The gene sequences and the primary structures of protein of TLR-3 andRLR have already been clarified. However, there is almost no findingpermitting analogical inference of the secondary structure and primarystructure of dsRNA that can be easily recognized by them. A singleavailable report teaches that polyA:U is recognized by TLR-3 but is noteasily recognized by RLR. There is no report on the inverse propertiesreported at this time; dsRNA that is recognized by RLR but not easilyrecognized by TLR-3.

The recognition property of TLR-3 and RLR can be evaluated usingcommercially available reporter cells. The TLR-3 recognition propertycan be evaluated using a cell obtained by incorporating TLR-3 gene andvarious NFκB inducible reporter genes into the genome of general cellssuch as 293 cell and the like and monitoring the level of activation ofNFκB induced by TLR-3 stimulation. RLR recognition property can beevaluated using a cell obtained by incorporating TLR-3 gene and variousNFκB and IRF3/7 inducible reporter genes into the genome of mouse fetalfibroblast that produces IFNβ in an RLR dependent manner, and monitoringthe level of activation of NFκB and IRF3/7 induced by RLR stimulation.

We examined the TLR-3 recognition property and RLR recognition propertyof various polyICs, produced by annealing polyI having different chainlengths and about 400 nt polyC, by using a reporter cell. As a result,we have found a new fact that the RLR recognition property is constantirrespective of the chain length of polyI, but the recognition propertyof TLR-3 decreases more from the polyI chain length of about 100 nt asthe length becomes shorter.

Experimental Example 2.1. Comparison of RLR Recognition Property

The RLR recognition property of various dsRNAs was evaluated bycomparison by using a reporter cell. RLR reporter cell C57/WT MEF(invivogen, USA) is a mouse primary fetal fibroblast strain introducedwith a secretive placenta alkaliphosphatase (ALP) reporter gene inducedby NF-κB and IRF3/7. Using this cell, the RLR recognition property ofdsRNA can be relatively compared based on the induction amount of ALP. Areporter assay using the C57/WT MEF cell was performed according to theprotocol of the maker. To be specific, C57/WT MEF was passage culturedin DMEM medium containing 10% bovine serum, the cell suspension thereofwas seeded in a 12 well plate at 1 ml/well, and the cells were subjectedto standing culture at 37° C., 5% CO₂ for about 20 hr. The medium wasexchanged with bovine serum-free DMEM medium (1 ml/well), various dsRNAs(100 ng) or PBS was added together with transfection reagent LyoVec(invivogen, USA), and the cells were subjected to standing culture at37° C., 5% CO₂. After 2 hr, bovine serum was added at 0.1 ml/well, thecells were further cultured for 22 hr, the culture supernatant wascollected and the secreted ALP was quantitatively analyzed. For thequantitative analysis of ALP, QuantiBlue kit (invivogen, USA) was used,and the results were converted to numerical values with E. coli-derivedALP (Takara Bio Inc., Japan) as the standard product. The resultsthereof are collectively shown in Table 11. Since the ALP inductionlevel does not change much depending on the dsRNA used, it was foundthat the RLR recognition property scarcely varies even when the chainlength ratio of ssRNA constituting dsRNA is changed.

TABLE 11 ssRNA species and weight ALP Found ALP induction average chainlength ¹⁾ level²⁾ first chain second chain μU/ml μU/ml relative % pI-400(389b) pC-400 64.4 43.5 100 (344b) pI-200 (188b) pC-400 65.7 44.8 103(344b) pI-100 (108b) pC-400 59.7 38.8 89 (344b) pI-50 (41b) pC-400 56.835.9 83 (344b) pI-25 (29b) pC-400 61.8 40.9 94 (344b) without additionof dsRNA 20.9 0 — (PBS was added) ¹⁾ SEAP analytical value, ²⁾amount ofincrease by dsRNA addition

Experimental Example 2.2. Comparison of TLR-3 Binding Property

The TLR-3 recognition properties of various dsRNAs were compared byreporter cell assay. TLR-3 reporter cell HEK-Blue hTLR3 cell (invivogen,USA) is a recombinant HEK-293 cell obtained by incorporating NF-κB andAP-1 inducible ALP gene and human TLR-3 gene into the genome. Using thiscell, the TLR-3 recognition property can be relatively compared based onthe induction amount of ALP. A reporter assay using the HEK-Blue hTLR3cell was performed according to the protocol of the maker. To bespecific, HEK-Blue hTLR3 was passage cultured in DMEM medium containing10% bovine serum supplemented with antibiotic Zeocin 100 mg/ml andantibiotic Blasticidin 10 mg/ml, the cell suspension thereof was seededin a 12 well plate at 1 ml/well, and the cells were subjected tostanding culture at 37° C., 5% CO₂ for about 44 hr. The medium wasexchanged with bovine serum-free DMEM medium (1 ml) containingantibiotic Zeocin (100 mg/ml) and antibiotic Blasticidin (10 mg/ml),various dsRNAs (100 ng) or PBS was added, and the cells were subjectedto standing culture at 37° C., 5% CO₂. After 2 hr from dsRNA addition,bovine serum was added at 0.1 ml/well, and 24 hr later, the culturesupernatant was collected and induction level of ALP was compared. Forthe quantitative analysis of ALP, QuantiBlue kit (invivogen, USA) wasused, and the results were converted to numerical values with E.coli-derived ALP (Takara Bio Inc., Japan) as the standard product. Theresults thereof are collectively shown in Table 12. As is clear fromTable 12, when the chain length of polyI reached 108 nt or below, theALP induction level decreased more as the chain length became shorter.That is, it was found that dsRNA showing completely new property thatonly the TLR-3 recognition property decreases while the RLR recognitionproperty is maintained can be produced by setting the chain length ofpolyI to 108 nt or below.

TABLE 12 ssRNA species and weight ALP ALP induction average chain lengthFound ¹⁾ level²⁾ first chain second chain μU/ml μU/ml relative % pI-400(389b) pC-400 (344b) 78.5 67.5 100 pI-200 (188b) pC-400 (344b) 76.2 65.297 pI-100 (108b) pC-400 (344b) 52.5 41.5 61 pI-50 (41b) pC-400 (344b)39.3 28.3 42 pI-25 (29b) pC-400 (344b) 15.8 4.8 7 without addition ofdsRNA 11.0 0 — (PBS was added) ¹⁾ SEAP analytical value, ²⁾amount ofincrease by dsRNA addition

Experimental Example 2.3. Experiment of TLR-3 Binding Property (NegativeControl)

HEK-Blue Null1 cell (invivogen, USA) is a parent cell of HEK-Blue hTLR3cell wherein only the human TLR-3 gene is not transfected, andcorresponds to a negative control of this strain. In completely the samemanner as in Experimental Example 2.2. except that HEK-Blue hTLR3 cellused in Experimental Example 2.2. was changed to HEK-Blue Null1 cell andantibiotic Blasticidin was not added to the medium, the test wasperformed to find that ALP was scarcely induced (Table 13). Therefore,it was confirmed that the ALP induction confirmed in ExperimentalExample 2.2. is a TLR-3 specific signal transduction.

TABLE 13 ssRNA species and weight ALP ALP induction average chain lengthFound ¹⁾ level ²⁾ first chain second chain μU/ml μU/ml pC-400 (344b)pI-400 (389b) 6.6 0.7 pI-200 (188b) pC-400 (344b) 6.8 0.9 pI-100 (108b)pC-400 (344b) 6.9 1.0 pI-50 (41b) pC-400 (344b) 6.2 0.3 pI-25 (29b)pC-400 (344b) 5.8 −0.1 without addition of dsRNA 5.9 0 (PBS was added)¹⁾ ALP analytical value, ²⁾ amount of increase by dsRNA addition

Experimental Example 3: Evaluation of Natural Immunity PotentiationActivity and Toxicity of Various PolyICs Background

To confirm whether dsRNA wherein the chain length of the first chainconstituting dsRNA is set to ½ or below to that of the second chainfunctions as a natural immunity potentiator, the strength of interferonβinducibility was evaluated by comparison in a cellular experiment.Furthermore, to confirm whether the toxicity of the dsRNA decreases,single administration toxicity evaluation was performed using a mouse.As a result of these two evaluations, it could be confirmed that thetoxicity is reduced while maintaining the natural immunity potentiationactivity even when the chain length of the first chain constitutingdsRNA is set to ½ or below to that of the second chain.

Experimental Example 3.1. Evaluation of Natural Immunity Inducibility

To evaluate the strength of the natural immunity inducibility essentialfor functioning as an adjuvant, interferon (IFN) β inducibility ofvarious dsRNAs was evaluated using human fetal fibroblast strain MRC-5(Japanese Collection of Research Bioresources Cell Bank No. 9008) usedfor the study of natural immunity. To be specific, MRC-5 was passagecultured in MEM medium containing 10% bovine serum, the cell suspensionthereof was seeded in a 12 well plate at 1 ml/well, and the cells weresubjected to standing culture at 37° C., 5% CO₂ for about 20 hr. Themedium was exchanged with bovine serum-free MEM medium (1 ml/well),various dsRNAs (30 μg) or PBS was added together with transfectionreagent LyoVec (invivogen, USA), and the cells were subjected tostanding culture at 37° C., 5% CO₂. After 2 hr, bovine serum was addedat 0.1 ml/well, and the cells were further cultured for 22 hr. Theculture supernatant was collected at 10 h, 24 h after dsRNA addition andIFNβ contained in the culture supernatant was quantitatively analyzed.For the quantitative analysis of IFNβ, IFNβ ELISA kit (KAMAKURATECHNO-SIENCE, INC., Japan) was used. The results thereof arecollectively shown in Table 14. Since the IFNβ induction level does notchange much depending on the dsRNA used, it was clarified that IFNβinducibility is maintained even when the chain length ratio of ssRNAconstituting dsRNA is changed.

TABLE 14 ssRNA species and weight average chain length IFNβ (IU/ml)first chain second chain 10 h later 24 h later pI-400 pC-400 (406b) 25140 (388b) pI-200 pC-400 (404b) 29 170 (205b) pI-100 pC-400 (402b) 37153 (96b) pI-50 (51b) pC-400 (405b) 39 197 without addition of dsRNA 0 0(PBS was added)

Experimental Example 3.2. Evaluation of Toxicity

PolyI:C produced using polyI and polyC having various chain lengths wasdissolved in saline to prepare solutions having a concentration of 5mg/ml to 20 mg/ml. These aqueous solutions were intraperitoneallyadministered once to healthy male Crlj:CD1 mice (6-week-old), and acutetoxicity was compared. Mice were housed in a mouse cage (5 per cage)placed under the environment of room temperature 22° C.+3° C., humidity55%±10%, ventilation frequency 10 times or more/h, illumination 12hr/day, and bred under the condition permitting free ingestion of waterand feed. About 1 week of acclimation period was set beforeintraperitoneal administration and, after administration, the mice werebred for 7 days counting the day of administration as day 1, andmonitored. Table 15 collectively shows the dose of polyI:C and survivalnumber after breeding for 7 days. The number of mice survived wasimproved by setting the chain length of the first chain to ½ or below tothat of the second chain. That is, decrease in the toxicity wasconfirmed.

TABLE 15 number of mice ssRNA species and weight survived/administrationnumber average chain length polyI:C dose (mg/kg/day) first chain secondchain 100 200 400 pI-400 (388b) pC-400 (406b) 2/5 0/5 — pI-200 (205b)pC-400 (404b) 5/5 2/5 0/5 pI-100 (96b) pC-400 (402b) 5/5 3/5 0/5 pI-50(51b) pC-400 (405b) 5/5 5/5 4/5

This application is based on patent application No. 2012-267012 filed inJapan (filing date: Dec. 6, 2012) and patent application No. 2013-145471filed in Japan (filing date: Jul. 11, 2013), the contents of which areincorporated in full herein.

1. A double-stranded ribonucleic acid (dsRNA) having a weight averagechain length within the range of 0.2 kilobase pairs (kbp) to 0.6 kbp, ora salt thereof, wherein the first chain of the dsRNA consists of two ormore polyinosinic acids having a weight average chain length of 0.1-0.2kilobase (kb), the second chain of the dsRNA consists of one ssRNAhaving a weight average chain length of 0.3-0.4 kb, which containscytidylic acid at a rate of not less than 80%, the dsRNA has a medianvalue of 0.1-0.35 kbp, and the weight average chain length of the two ormore polyinosinic acids constituting the first chain is not more than ½to the weight average chain length of one ssRNA which contains cytidylicacid at a ratio of not less than 80% constituting the second chain.